from __future__ import annotations

import copy
import logging
import os
import time
import warnings
from builtins import classmethod
from functools import partial
from pathlib import Path
from typing import Dict, Union

import numpy as np
import pandas as pd
import sklearn

from autogluon.common.features.types import (
    R_BOOL,
    R_CATEGORY,
    R_DATETIME,
    R_FLOAT,
    R_INT,
    R_OBJECT,
    S_TEXT_AS_CATEGORY,
    S_TEXT_NGRAM,
    S_TEXT_SPECIAL,
)
from autogluon.common.utils.pandas_utils import get_approximate_df_mem_usage
from autogluon.common.utils.resource_utils import ResourceManager
from autogluon.common.utils.try_import import try_import_fastai
from autogluon.core.constants import BINARY, QUANTILE, REGRESSION
from autogluon.core.hpo.constants import RAY_BACKEND
from autogluon.core.models import AbstractModel
from autogluon.core.utils.exceptions import TimeLimitExceeded
from autogluon.core.utils.files import make_temp_directory
from autogluon.core.utils.loaders import load_pkl
from autogluon.core.utils.savers import save_pkl
from autogluon.tabular.models.tabular_nn.utils.nn_architecture_utils import infer_y_range

from .hyperparameters.parameters import get_param_baseline
from .hyperparameters.searchspaces import get_default_searchspace

# FIXME: Has a leak somewhere, training additional models in a single python script will slow down training for each additional model. Gets very slow after 20+ models (10x+ slowdown)
#  Slowdown does not appear to impact Mac OS
# Reproduced with raw torch: https://github.com/pytorch/pytorch/issues/31867
# https://forums.fast.ai/t/runtimeerror-received-0-items-of-ancdata/48935
# https://github.com/pytorch/pytorch/issues/973
# https://pytorch.org/docs/master/multiprocessing.html#file-system-file-system
# Slowdown bug not experienced on Linux if 'torch.multiprocessing.set_sharing_strategy('file_system')' commented out
# NOTE: If below line is commented out, Torch uses many file descriptors. If issues arise, increase ulimit through 'ulimit -n 2048' or larger. Default on Linux is 1024.
# torch.multiprocessing.set_sharing_strategy('file_system')

# MacOS issue: torchvision==0.7.0 + torch==1.6.0 can cause segfaults; use torch==1.2.0 torchvision==0.4.0

LABEL = "__label__"

logger = logging.getLogger(__name__)


# TODO: Takes extremely long time prior to training start if many (10000) continuous features from ngrams, debug - explore TruncateSVD option to reduce input dimensionality
# TODO: currently fastai automatically detect and use CUDA if available - add code to honor autogluon settings
class NNFastAiTabularModel(AbstractModel):
    """Class for fastai v1 neural network models that operate on tabular data.

    Hyperparameters:
        'y_scaler': on regression problems, the model can give unreasonable predictions on unseen data.
        To address this problem, AutoGluon scales y values by default for regression problems.
        This attribute allows to pass a custom scaler for y values. Please note that intermediate
        iteration metrics will be affected by this transform and as a result intermediate iteration scores will be
        different from the final ones (these will be correct).
        https://scikit-learn.org/stable/modules/classes.html#module-sklearn.preprocessing

        'clipping': on regression problems, extreme outliers of y can hurt performance of the model during training and
        on unseen data. To address this problem, AutoGluon clips input y values and output predictions by default to a
        range inferred from the training data. Setting this attribute to False disables clipping.

        'layers': list of hidden layers sizes; None - use model's heuristics; default is None

        'emb_drop': embedding layers dropout; default is 0.1

        'ps': linear layers dropout - list of values applied to every layer in `layers`; default is [0.1]

        'bs': batch size; default is 256

        'lr': maximum learning rate for one cycle policy; default is 1e-2;
        see also https://docs.fast.ai/callback.schedule.html#Learner.fit_one_cycle,
        One-cycle policy paper: https://arxiv.org/abs/1803.09820

        'epochs': number of epochs; default is 30

        # Early stopping settings. See more details here: https://docs.fast.ai/callback.tracker.html#EarlyStoppingCallback
        'early.stopping.min_delta': 0.0001,
        'early.stopping.patience': 10,
    """

    model_internals_file_name = "model-internals.pkl"

    def __init__(self, **kwargs):
        super().__init__(**kwargs)
        self.cat_columns = None
        self.cont_columns = None
        self.columns_fills = None
        self._columns_fills_names = None
        self.procs = None
        self.y_scaler = None
        self._cont_normalization = None
        self._load_model = None  # Whether to load inner model when loading.
        self._num_cpus_infer = None
        self.clipping = None

    def _preprocess_train(self, X, y, X_val, y_val):
        from fastai.data.block import CategoryBlock, RegressionBlock
        from fastai.data.transforms import IndexSplitter
        from fastai.tabular.core import TabularPandas
        from fastcore.basics import range_of

        X = self.preprocess(X, fit=True)
        if X_val is not None:
            X_val = self.preprocess(X_val)

        from fastai.tabular.core import Categorify

        self.procs = [Categorify]

        if self.problem_type in [REGRESSION, QUANTILE] and self.y_scaler is not None:
            y_norm = pd.Series(self.y_scaler.fit_transform(y.values.reshape(-1, 1)).reshape(-1))
            y_val_norm = pd.Series(self.y_scaler.transform(y_val.values.reshape(-1, 1)).reshape(-1)) if y_val is not None else None
            logger.log(0, f"Training with scaled targets: {self.y_scaler} - !!! NN training metric will be different from the final results !!!")
        else:
            y_norm = y
            y_val_norm = y_val

        logger.log(15, f"Using {len(self.cont_columns)} cont features")
        df_train, train_idx, val_idx = self._generate_datasets(X, y_norm, X_val, y_val_norm)
        y_block = RegressionBlock() if self.problem_type in [REGRESSION, QUANTILE] else CategoryBlock()

        # Copy cat_columns and cont_columns because TabularList is mutating the list
        data = TabularPandas(
            df_train,
            cat_names=self.cat_columns.copy(),
            cont_names=self.cont_columns.copy(),
            procs=self.procs,
            y_block=y_block,
            y_names=LABEL,
            splits=IndexSplitter(val_idx)(range_of(df_train)),
        )
        return data

    def _preprocess(self, X: pd.DataFrame, fit=False, **kwargs):
        X = super()._preprocess(X=X, **kwargs)
        if fit:
            self.cont_columns = self._feature_metadata.get_features(valid_raw_types=[R_INT, R_FLOAT, R_DATETIME])
            self.cat_columns = self._feature_metadata.get_features(valid_raw_types=[R_OBJECT, R_CATEGORY, R_BOOL])
            if self.cont_columns:
                self._cont_normalization = (np.array(X[self.cont_columns].mean()), np.array(X[self.cont_columns].std()))

            num_cat_cols_og = len(self.cat_columns)
            if self.cat_columns:
                try:
                    X_stats = X[self.cat_columns].describe(include="all").T.reset_index()
                    cat_cols_to_drop = list(
                        X_stats[(X_stats["unique"] > self.params.get("max_unique_categorical_values", 10000)) | (X_stats["unique"].isna())]["index"].values
                    )
                except:
                    cat_cols_to_drop = []
                if len(cat_cols_to_drop) != 0:
                    cat_cols_to_drop = set(cat_cols_to_drop)
                    self.cat_columns = [col for col in self.cat_columns if (col not in cat_cols_to_drop)]
            num_cat_cols_use = len(self.cat_columns)
            logger.log(15, f"Using {num_cat_cols_use}/{num_cat_cols_og} categorical features")

            nullable_numeric_features = self._feature_metadata.get_features(valid_raw_types=[R_FLOAT, R_DATETIME], invalid_special_types=[S_TEXT_SPECIAL])
            self.columns_fills = dict()
            self._columns_fills_names = nullable_numeric_features
            for c in self._columns_fills_names:  # No need to do this for int features, int can't have null
                self.columns_fills[c] = X[c].mean()
        X = self._fill_missing(X)
        if self.cont_columns:
            cont_mean, cont_std = self._cont_normalization
            # Creating a new DataFrame is 10x+ faster than assigning results to X[self.cont_columns]
            X_cont = pd.DataFrame(
                (X[self.cont_columns].values - cont_mean) / cont_std,
                columns=self.cont_columns,
                index=X.index,
            )
            if self.cat_columns:
                # Creating a new DataFrame via concatenation is faster than editing values in-place
                X = pd.concat([X_cont, X[self.cat_columns]], axis=1)
            else:
                X = X_cont.copy()
        return X

    def _fill_missing(self, df: pd.DataFrame) -> pd.DataFrame:
        # FIXME: Consider representing categories as int
        if self.columns_fills:
            # Speed up preprocessing by only filling columns where NaNs are present
            is_null = df[self._columns_fills_names].isnull().values.max(axis=0)
            columns_to_fill = [self._columns_fills_names[i] for i in range(len(is_null)) if is_null[i]]
            column_fills = {k: self.columns_fills[k] for k in columns_to_fill}
            if column_fills:
                # TODO: pandas==1.5.3 fillna is 10x+ slower than pandas==1.3.5 with large column count
                # TODO: Remove warning later as a follow up to https://github.com/autogluon/autogluon/pull/3734
                with warnings.catch_warnings():
                    warnings.simplefilter(action="ignore", category=FutureWarning)
                    df = df.fillna(column_fills, inplace=False, downcast=False)
            else:
                df = df.copy()
        else:
            df = df.copy()
        return df

    def _fit(self, X, y, X_val=None, y_val=None, time_limit=None, num_cpus=None, num_gpus=0, sample_weight=None, **kwargs):
        try_import_fastai()
        import torch
        from fastai import torch_core
        from fastai.tabular.learner import tabular_learner
        from fastai.tabular.model import tabular_config

        from .callbacks import AgSaveModelCallback, EarlyStoppingCallbackWithTimeLimit
        from .quantile_helpers import HuberPinballLoss

        torch.set_num_threads(num_cpus)
        start_time = time.time()
        if sample_weight is not None:  # TODO: support
            logger.log(15, "sample_weight not yet supported for NNFastAiTabularModel, this model will ignore them in training.")

        params = self._get_model_params()
        self._num_cpus_infer = params.pop("_num_cpus_infer", 1)

        self.y_scaler = params.get("y_scaler", None)
        if self.y_scaler is None:
            if self.problem_type == REGRESSION:
                self.y_scaler = sklearn.preprocessing.StandardScaler()
            elif self.problem_type == QUANTILE:
                self.y_scaler = sklearn.preprocessing.MinMaxScaler()
        else:
            self.y_scaler = copy.deepcopy(self.y_scaler)

        self.clipping = params.pop("clipping", True)
        if self.clipping and (self.problem_type == REGRESSION):
            # use code and concepts from TorchNN to infer y range. 0.05 follows default from TorchNN.
            y_min, y_max = infer_y_range(y, y_range_extend=0.05)
            clip_func = partial(np.clip, a_min=y_min, a_max=y_max)

            steps = [
                # needs both func and inverse func, as the FastAI model calls inverse_transform.
                ("clipper", sklearn.preprocessing.FunctionTransformer(func=clip_func, inverse_func=clip_func)),
            ]

            # Support the case where no scaler is defined.
            if self.y_scaler is not None:
                steps.append(("scaler", self.y_scaler))

            self.y_scaler = sklearn.pipeline.Pipeline(steps=steps)

        if num_gpus is not None:
            # TODO: Control CPU vs GPU usage during inference
            if num_gpus == 0:
                torch_core.default_device(False)
            else:
                # TODO: respect CUDA_VISIBLE_DEVICES to select proper GPU
                torch_core.default_device(True)

        logger.log(15, f"Fitting Neural Network with parameters {params}...")
        data = self._preprocess_train(X, y, X_val, y_val)

        nn_metric, objective_func_name = self.__get_objective_func_name(self.stopping_metric)
        objective_func_name_to_monitor = self.__get_objective_func_to_monitor(objective_func_name)
        objective_optim_mode = (
            np.less
            if objective_func_name
            in [
                "log_loss",
                "root_mean_squared_error",
                "mean_squared_error",
                "mean_absolute_error",
                "median_absolute_error",  # Regression objectives
                "pinball_loss",  # Quantile objective
            ]
            else np.greater
        )

        # TODO: calculate max emb concat layer size and use 1st layer as that value and 2nd in between number of classes and the value
        if params.get("layers", None) is not None:
            layers = params["layers"]
            if isinstance(layers, tuple):
                layers = list(layers)
        elif self.problem_type in [REGRESSION, BINARY]:
            layers = [200, 100]
        elif self.problem_type == QUANTILE:
            base_size = max(len(self.quantile_levels) * 4, 128)
            layers = [base_size, base_size, base_size]
        else:
            base_size = max(data.c * 2, 100)
            layers = [base_size * 2, base_size]

        loss_func = None
        if self.problem_type == QUANTILE:
            loss_func = HuberPinballLoss(self.quantile_levels, alpha=self.params["alpha"])

        best_epoch_stop = params.get("best_epoch", None)  # Use best epoch for refit_full.
        batch_size = self._get_batch_size(X)
        dls = data.dataloaders(bs=batch_size)

        # Make deterministic
        from fastai.torch_core import set_seed

        set_seed(0, True)
        dls.rng.seed(0)

        if self.problem_type == QUANTILE:
            dls.c = len(self.quantile_levels)

        self.model = tabular_learner(
            dls,
            layers=layers,
            metrics=nn_metric,
            config=tabular_config(ps=params["ps"], embed_p=params["emb_drop"]),
            loss_func=loss_func,
        )
        logger.log(15, self.model.model)

        fname = "model"
        save_callback = AgSaveModelCallback(
            monitor=objective_func_name_to_monitor, comp=objective_optim_mode, fname=fname, best_epoch_stop=best_epoch_stop, with_opt=True
        )

        if time_limit is not None:
            time_elapsed = time.time() - start_time
            time_left = time_limit - time_elapsed
            if time_left <= time_limit * 0.7:  # if 30% of time was spent preprocessing, likely not enough time to train model
                raise TimeLimitExceeded
        else:
            time_left = None

        early_stopping = EarlyStoppingCallbackWithTimeLimit(
            monitor=objective_func_name_to_monitor,
            comp=objective_optim_mode,
            min_delta=params["early.stopping.min_delta"],
            patience=params["early.stopping.patience"],
            time_limit=time_left,
            best_epoch_stop=best_epoch_stop,
        )

        callbacks = [save_callback, early_stopping]

        with make_temp_directory() as temp_dir:
            with self.model.no_bar():
                with self.model.no_logging():
                    original_path = self.model.path
                    self.model.path = Path(temp_dir)

                    len_val = len(X_val) if X_val is not None else 0
                    epochs = self._get_epochs_number(samples_num=len(X) + len_val, epochs=params["epochs"], batch_size=batch_size, time_left=time_left)
                    if epochs == 0:
                        # Stop early if there is not enough time to train a full epoch
                        raise TimeLimitExceeded

                    self.model.fit_one_cycle(epochs, params["lr"], cbs=callbacks)

                    # Load the best one and export it
                    self.model = self.model.load(fname)

                    if objective_func_name == "log_loss":
                        eval_result = self.model.validate(dl=dls.valid)[0]
                    else:
                        eval_result = self.model.validate(dl=dls.valid)[1]

                    logger.log(15, f"Model validation metrics: {eval_result}")
                    self.model.path = original_path

            self.params_trained["epochs"] = epochs
            self.params_trained["best_epoch"] = save_callback.best_epoch

    def _get_batch_size(self, X, default_batch_size_for_small_inputs=32):
        bs = self.params["bs"]
        if bs == "auto":
            bs = 512 if len(X) >= 200000 else 256
        bs = bs if len(X) > bs else default_batch_size_for_small_inputs

        if self.params["bs"] == "auto":
            logger.log(15, f"Automated batch size selection: {bs}")

        return bs

    def _get_epochs_number(
        self,
        samples_num: int,
        epochs: int | str,
        batch_size: int,
        time_left: float | None = None,
        min_batches_count: int = 30,
        default_epochs: int = 30,
    ) -> int:
        """Get the number of epochs to train during fit"""
        if epochs == "auto":
            batches_count = int(samples_num / batch_size) + 1
            if not time_left:
                return default_epochs
            elif batches_count < min_batches_count:
                return default_epochs
            else:
                est_batch_time = self._measure_batch_times(min_batches_count)
                est_epoch_time = batches_count * est_batch_time * 1.1
                est_max_epochs = int(time_left / est_epoch_time)
                epochs = min(default_epochs, est_max_epochs)
                epochs = max(epochs, 0)
                logger.log(
                    15,
                    f"Automated epochs selection: training for {epochs} epoch(s). Estimated time budget use {epochs * est_epoch_time:.2f} / {time_left:.2f} sec",
                )
        return epochs

    def _measure_batch_times(self, min_batches_count: int) -> float:
        """Returns the time in seconds taken to fit a single batch"""
        from fastai.callback.core import CancelFitException

        from .callbacks import BatchTimeTracker

        batch_time_tracker_callback = BatchTimeTracker(batches_to_measure=min_batches_count)
        try:
            with self.model.no_bar():
                with self.model.no_logging():
                    self.model.fit(1, lr=0, cbs=[batch_time_tracker_callback])
        except CancelFitException:
            pass  # expected early exit
        batch_time = batch_time_tracker_callback.batch_measured_time
        if batch_time is None or batch_time < 0.00001:
            # Fixes rare issue where batch_time = None if the operation occurs too quickly
            batch_time = 0.00001
        return batch_time

    def _generate_datasets(self, X, y, X_val, y_val):
        df_train = pd.concat([X, X_val], ignore_index=True)
        df_train[LABEL] = pd.concat([y, y_val], ignore_index=True)
        train_idx = np.arange(len(X))
        if X_val is None:
            # use validation set for refit_full case - it's not going to be used for early stopping
            val_idx = np.array([0, 1]) + len(train_idx)
            df_train = pd.concat([df_train, df_train[:2]], ignore_index=True)
        else:
            val_idx = np.arange(len(X_val)) + len(X)
        return df_train, train_idx, val_idx

    def __get_objective_func_name(self, stopping_metric):
        metrics_map = self.__get_metrics_map()

        # Unsupported metrics will be replaced by defaults for a given problem type
        objective_func_name = stopping_metric.name
        if objective_func_name not in metrics_map.keys():
            if self.problem_type == REGRESSION:
                objective_func_name = "mean_squared_error"
            elif self.problem_type == QUANTILE:
                objective_func_name = "pinball_loss"
            else:
                objective_func_name = "log_loss"
            logger.warning(f"Metric {stopping_metric.name} is not supported by this model - using {objective_func_name} instead")

        nn_metric = metrics_map.get(objective_func_name, None)

        return nn_metric, objective_func_name

    def __get_objective_func_to_monitor(self, objective_func_name):
        monitor_obj_func = {
            **{k: m.name if hasattr(m, "name") else m.__name__ for k, m in self.__get_metrics_map().items() if m is not None},
            "log_loss": "valid_loss",
        }
        objective_func_name_to_monitor = objective_func_name
        if objective_func_name in monitor_obj_func:
            objective_func_name_to_monitor = monitor_obj_func[objective_func_name]
        return objective_func_name_to_monitor

    def _predict_proba(self, X, **kwargs):
        X = self.preprocess(X, **kwargs)

        single_row = len(X) == 1
        # fastai has issues predicting on a single row, duplicating the row as a workaround
        if single_row:
            X = pd.concat([X, X]).reset_index(drop=True)
        # Copy cat_columns and cont_columns because TabularList is mutating the list
        # TODO: This call has very high fixed cost with many features (0.7s for a single row with 3k features)
        #  Primarily due to normalization performed on the inputs
        test_dl = self.model.dls.test_dl(X, inplace=True)
        with self.model.no_bar():
            with self.model.no_logging():
                preds, _ = self.model.get_preds(dl=test_dl)
        if single_row:
            preds = preds[:1, :]
        if self.problem_type == REGRESSION:
            if self.y_scaler is not None:
                return self.y_scaler.inverse_transform(preds.numpy()).reshape(-1)
            else:
                return preds.numpy().reshape(-1)
        elif self.problem_type == QUANTILE:
            from .quantile_helpers import isotonic

            if self.y_scaler is not None:
                preds = self.y_scaler.inverse_transform(preds.numpy()).reshape(-1, len(self.quantile_levels))
            else:
                preds = preds.numpy().reshape(-1, len(self.quantile_levels))
            return isotonic(preds, self.quantile_levels)
        elif self.problem_type == BINARY:
            return preds[:, 1].numpy()
        else:
            return preds.numpy()

    def save(self, path: str = None, verbose=True) -> str:
        from .fastai_helpers import export

        self._load_model = self.model is not None
        __model = self.model
        self.model = None
        path = super().save(path=path, verbose=verbose)
        self.model = __model
        # Export model
        if self._load_model:
            save_pkl.save_with_fn(self._model_internals_path, self.model, pickle_fn=lambda m, buffer: export(m, buffer), verbose=verbose)
        self._load_model = None
        return path

    @classmethod
    def load(cls, path: str, reset_paths=True, verbose=True):
        from fastai.learner import load_learner

        model = super().load(path, reset_paths=reset_paths, verbose=verbose)
        if model._load_model:
            # Need the following logic to allow cross os loading of fastai model
            # https://github.com/fastai/fastai/issues/1482
            import pathlib
            import platform

            plt = platform.system()
            og_windows_path = None
            if plt != "Windows":
                og_windows_path = pathlib.WindowsPath
                pathlib.WindowsPath = pathlib.PosixPath
            model_internals_path = os.path.join(path, model.model_internals_file_name)
            model.model = load_pkl.load_with_fn(model_internals_path, lambda p: load_learner(p), verbose=verbose)
            if og_windows_path is not None:
                pathlib.WindowsPath = og_windows_path
        model._load_model = None
        return model

    @property
    def _model_internals_path(self) -> str:
        """Path to model-internals.pkl"""
        return os.path.join(self.path, self.model_internals_file_name)

    def _set_default_params(self):
        """Specifies hyperparameter values to use by default"""
        default_params = get_param_baseline(self.problem_type)
        for param, val in default_params.items():
            self._set_default_param_value(param, val)

    def _get_default_searchspace(self):
        return get_default_searchspace(self.problem_type, num_classes=None)

    def _get_default_auxiliary_params(self) -> dict:
        default_auxiliary_params = super()._get_default_auxiliary_params()
        extra_auxiliary_params = dict(
            valid_raw_types=[R_BOOL, R_INT, R_FLOAT, R_CATEGORY],
            ignored_type_group_special=[S_TEXT_NGRAM, S_TEXT_AS_CATEGORY],
        )
        default_auxiliary_params.update(extra_auxiliary_params)
        return default_auxiliary_params

    def _get_default_resources(self):
        # logical=False is faster in training
        num_cpus = ResourceManager.get_cpu_count_psutil(logical=False)
        num_gpus = 0
        return num_cpus, num_gpus

    def __get_metrics_map(self):
        from fastai.metrics import FBeta, Precision, R2Score, Recall, RocAucBinary, accuracy, mae, mse, rmse

        from .fastai_helpers import medae
        from .quantile_helpers import HuberPinballLoss

        metrics_map = {
            # Regression
            "root_mean_squared_error": rmse,
            "mean_squared_error": mse,
            "mean_absolute_error": mae,
            "r2": R2Score(),
            "median_absolute_error": medae,
            # Classification
            "accuracy": accuracy,
            "f1": FBeta(beta=1),
            "f1_macro": FBeta(beta=1, average="macro"),
            "f1_micro": FBeta(beta=1, average="micro"),
            "f1_weighted": FBeta(beta=1, average="weighted"),  # this one has some issues
            "roc_auc": RocAucBinary(),
            "precision": Precision(),
            "precision_macro": Precision(average="macro"),
            "precision_micro": Precision(average="micro"),
            "precision_weighted": Precision(average="weighted"),
            "recall": Recall(),
            "recall_macro": Recall(average="macro"),
            "recall_micro": Recall(average="micro"),
            "recall_weighted": Recall(average="weighted"),
            "log_loss": None,
            "pinball_loss": HuberPinballLoss(quantile_levels=self.quantile_levels),
            # Not supported: pac_score
        }
        return metrics_map

    def _estimate_memory_usage(self, X, **kwargs):
        return 10 * get_approximate_df_mem_usage(X).sum()

    def _get_hpo_backend(self):
        """Choose which backend(Ray or Custom) to use for hpo"""
        return RAY_BACKEND

    def _get_maximum_resources(self) -> Dict[str, Union[int, float]]:
        # fastai model trains slower when utilizing virtual cores and this issue scale up when the number of cpu cores increases
        return {"num_cpus": ResourceManager.get_cpu_count_psutil(logical=False)}

    def get_minimum_resources(self, is_gpu_available=False):
        minimum_resources = {
            "num_cpus": 1,
        }
        if is_gpu_available:
            minimum_resources["num_gpus"] = 0.5
        return minimum_resources

    def _more_tags(self):
        return {"can_refit_full": True}
